Departamento de Fisiologia e Farmacologia, Centro de Biociências, Universidade Federal do Pernambuco, Recife, Brazil.
Champalimaud Research, Champalimaud Centre for the Unknown, Lisbon, Portugal.
J Mater Sci Mater Med. 2018 Aug 17;29(9):139. doi: 10.1007/s10856-018-6147-0.
Bacteria-synthesized polysaccharides have attracted interest for biomedical applications as promising biomaterials to be used as implants and scaffolds. The present study tested the hypothesis that cellulose exopolysaccharide (CEC) produced from sugarcane molasses of low cost and adequate purity would be suitable as a template for 2D and 3D neuron and/or astrocyte primary cultures, considering its low toxicity. CEC biocompatibility in these primary cultures was evaluated with respect to cell viability, adhesion, growth and cell function (calcium imaging). Polystyrene or Matrigel® matrix were used as comparative controls. We demonstrated that the properties of this CEC in the 2D or 3D configurations are suitable for differentiation of cortical astrocytes and neurons in single or mixed cultures. No toxicity was detected in neurons that showed NMDA-induced Ca influx. Unlike other polysaccharides of bacterial synthesis, the CEC was efficient as a support even in the absence of surface conjugation with extracellular matrix proteins, maintaining physiological characteristics of cultured neural cells. These observations open up the perspective for development of a novel 3D biofunctional scaffold produced from bacterial cellulose and obtained from renewable sources whose residues are not pollutants. Its low cost and possibility to be manufactured in scale are also suitable for potential applications in regenerative medicine.
细菌合成的多糖作为有前途的生物材料,已被用于植入物和支架等生物医学应用,引起了人们的兴趣。本研究测试了以下假设:从低成本和足够纯度的甘蔗糖蜜中提取的纤维素胞外多糖(CEC)将适合作为二维和三维神经元和/或星形胶质细胞原代培养的模板,因为它的毒性较低。通过细胞活力、黏附、生长和细胞功能(钙成像)评估 CEC 在这些原代培养物中的生物相容性。聚苯乙烯或 Matrigel®基质被用作比较对照。我们证明,这种 CEC 在 2D 或 3D 结构中的特性适合于在单一或混合培养物中分化皮质星形胶质细胞和神经元。在显示 NMDA 诱导的 Ca 内流的神经元中未检测到毒性。与其他细菌合成的多糖不同,CEC 即使在没有与细胞外基质蛋白表面偶联的情况下,也是一种有效的支持物,维持了培养神经细胞的生理特性。这些观察结果为开发一种新型的 3D 生物功能支架开辟了前景,该支架由细菌纤维素制成,且来源于可再生资源,其残留物不是污染物。其低成本和规模化生产的可能性也适合于再生医学的潜在应用。
